Power-Split Continuously Variable Transmission Device

ABSTRACT

A variator unit of a power-split continuously variable transmission is fixed to a rotationally fixed component and has a primary side rotationally fixed to an input shaft and a secondary side rotationally fixed to a first element of a second planetary gear set via a third shaft. A third element of a first planetary gear set is rotationally fixed via a fourth shaft to a second element of the second planetary gear set, which is fixable to the rotationally fixed component via a first shift element and connectable to the input shaft via a second shift element. A third element of the second planetary gear set is rotationally fixed via a fifth shaft to a first element of the first planetary gear set fixable to the rotationally fixed component via a third shift element. The second element of the first planetary gear set is rotationally fixed to an output shaft.

FIELD OF THE INVENTION

The present invention relates to a power-split continuously variable transmission device, in particular a continuously variable planetary transmission. The invention further relates to a motor vehicle drive train have a power-split continuously variable transmission device.

BACKGROUND

US20160109002A1 describes such a continuously variable transmission which is considered to be the closest prior art.

WO2014179717 also describes a continuously variable transmission, having a NuVinci variator, a plus planetary gear set, a minus planetary gear set, and an arrangement of multiple clutches, which makes two forward modes and one reverse mode available.

Continuously variable transmissions, which are also referred to as CVT transmissions, can continuously control the transmission ratio between the lowest and the highest ratios, for example, with the aid of a so-called variator. This is different from typical transmissions, in which a number of predetermined (discrete) transmission ratios are provided. A CVT transmission can be a mechanical continuously variable transmission, for example, in the form of a flexible traction drive mechanism or a friction drive such as a cone ring or toroidal transmission.

The basic active principles of mechanical continuously variable transmissions are always the same, regardless of their construction. The power transmission takes place, without conversion of the form of energy, in a force-locking manner, by way of the friction-locking contact of two or more contact bodies which are moving relative to each other and which are usually referred to as a primary and a secondary disk, which are also referred to as a primary and a secondary side, wherein the two disks are formed from conical disks arranged in pairs and are provided with a torque-transmitting wrap-around element which revolves between the two pairs of conical disks.

Depending on the type of construction, very high full-load efficiencies are possible, which substantially exceed those of the hydrostatic transmission. The transmission ratio of mechanical CVTs is always determined by their active friction radii ratio, i.e., the current ratio is defined by the running radius of the wrap-around element, which, in turn, is a function of the axial position of the conical disks and, therefore, is subjected to geometric limits which prevent an immediate implementation of the starting process.

In order to overcome these limitations on the overall gear ratio of mechanical CVTs, it is useful to operate the mechanical CVTs in power-splitting transmission structures, such as in a combination of one or multiple planetary transmissions comprising a continuously variable transmission. Such a transmission, which is also referred to as an IVT transmission (infinitely variable transmission), can gear down between a fixed ratio value and any reduced speed in one transmission direction, i.e., infinitely, or even in the opposite direction, i.e., negatively, and so the input shaft rotates while the output shaft is at a standstill.

In the case of such a transmission, therefore, the spread of gear ratios of the variator are expandable, by reactive power-based operation at low speeds, in such a way that an immediate implementation of the starting process becomes possible, i.e., the vehicle is at a standstill with an “infinite” ratio, while the engine is running, without an additional separating clutch.

Due to the utilization as a power-split transmission, the power flow is guidable along one or multiple power paths. For example, the power is guidable along a first path by the variator or along a second path by way of the planetary transmission. The power is also returnable into the variator, whereby the load on the variator is increased during the operation of the continuously variable transmission.

The problem addressed by the present invention is that of making an alternative continuously variable transmission available, which has a simple configuration and a compact design.

SUMMARY OF THE INVENTION

According to the invention, the transmission device includes an input shaft and an output shaft, a first planetary gear set which is arranged between the input shaft and the output shaft, a second planetary gear set which is connected to the first planetary gear set and is arranged between the input shaft and the output shaft, a variator unit which transmits power in an infinitely variable manner from the input shaft to the first planetary gear set. The variator unit includes a first shift element, a second shift element, and a third shift element, the selective actuation of which implements different power paths via the variator unit and the planetary gear sets while making a first mode, a second mode, and a third mode available.

Within the meaning of the invention, a “shaft” is understood to be a rotatable component of the transmission, via which associated components of the transmission are axially and/or radially rotationally fixed to each other or via which a connection of this type is established upon actuation of an appropriate shift element. The respective shaft can therefore also be an intermediate piece, via which a respective component is connected, for example, radially.

The invention now encompasses the technical teaching that the variator unit is fixed to a rotationally fixed component, a primary side of the variator unit is rotationally fixed to the input shaft, and a secondary side of the variator unit is rotationally fixed to a first element of the second planetary gear set via a third shaft.

A third element of the first planetary gear set is rotationally fixed via a fourth shaft to a second element of the second planetary gear set, which is also fixable to the rotationally fixed component via the first shift element and connectable to the input shaft via the second shift element.

A third element of the second planetary gear set is rotationally fixed via a fifth shaft to a first element of the first planetary gear set, which is also fixable to the rotationally fixed component via the third shift element, and the second element of the first planetary gear set is rotationally fixed to the output shaft.

In other words, in the transmission device according to the invention, the input shaft is permanently rotationally fixed to the variator unit, while the output shaft is rotationally fixed to the second element of the first planetary gear set.

Upon actuation of the first shift element, the fourth shaft of the transmission device and, therefore, the third element of the first planetary gear set and the second element of the second planetary gear set are fixed to a rotationally fixed component and, therefore, are prevented from making a turning motion, while, upon actuation of the third shift element, the fifth shaft and, therefore, the third element of the second planetary gear set and the first element of the first planetary gear set are fixed to the rotationally fixed component. Upon actuation of the second shift element, the fourth shaft and, therefore, the third element of the first planetary gear set as well as the second element of the second planetary gear set are rotationally fixed to the input shaft.

The rotationally fixed component of the transmission is, according to the invention, a permanently non-rotating component of the transmission, preferably a transmission housing or a part of a transmission housing of this type.

In the transmission according to the invention, each of the first shift element and the third shift element is a brake which, upon actuation, decelerates a particular associated component of the transmission to a standstill and fixes the component against the rotationally fixed component. By contrast, the second shift element is a clutch which, upon actuation, synchronizes the turning motions of the associated rotatable components of the transmission device and subsequently rotationally fixes these to each other.

A respective rotationally fixed connection of the rotatable elements of the planetary gear sets is preferably implemented, according to the invention, via one or even multiple intermediate shafts which can also be present, in this case, as short axial and/or radial intermediate pieces when the elements are positioned in a spatially dense manner. Specifically, the elements of the planetary gear sets, which are permanently rotationally fixed to each other, can each be present either as several individual components which are rotationally fixed together, or even a single piece. In the second case mentioned above, the respective elements and the optionally present shaft are then formed by one common component, wherein this is implemented, in particular, when the respective elements lie spatially close to each other in the transmission.

In the case of elements of the planetary gear sets, which are rotationally fixed to each other only upon actuation of a respective shift element, a connection is also preferably achieved via one or even multiple intermediate shafts.

It has been found that, by way of the invention, a transmission device is made available, which has a simple configuration including only two planetary gear sets and three shift elements, has a compact design and, in addition, is distinguished by the fact that transmission losses are low. In contrast to the closest prior art, where the variator unit is bridged for individual modes, according to the invention, the power is always at least partially implementable via the variator unit, i.e., the variator unit is involved in all three modes. In addition, the transmission device has only low component loads and, in particular, a low variator load. The transmission device is particularly suitable as a front-transverse or rear-transverse arrangement including a lateral driven end.

In principle, the most common mechanical, hydrostatic, or electric variators are conceivable. Exemplary embodiments of mechanical variators are NuVinci, cone ring, and planetary roller variators. One exemplary embodiment of hydrostatic variators is two hydrostatic transmissions. One exemplary embodiment of electric variators is two electric machines.

According to one embodiment, it is preferred, however, that the variator is a mechanical variator, particularly preferred, a NuVinci variator or a planetary roller variator, since such a variator does not have a reversal of the direction of rotation between the two sides of the variator.

Moreover, it is preferred that the two planetary gear sets are arranged axially adjacent to each other, originating from a mounting interface of the input shaft of the transmission device. Within the meaning of the invention, the term “axially” means an orientation in the direction of an axis along which the first planetary gear set and the second planetary gear set are arranged coaxially to each other.

In one alternative embodiment, it is preferred that the first planetary gear set is arranged radially outside the second planetary gear set. As a result, an even more axially compact type of construction can be achieved. “Radially” is then understood to mean an orientation in the direction of the diameter of a shaft lying on this axis.

It is preferred that each of the first and second planetary gear sets is a minus planetary gear set, wherein the first element of the first planetary gear set is a sun gear, the second element of the first planetary gear set is a planet carrier, and the third element of the first planetary gear set is a ring gear, wherein the first element of the second planetary gear set is a sun gear, the second element of the second planetary gear set is a planet carrier, and the third element of the second planetary gear set is a ring gear.

The minus planetary gear set is also known as a simple planetary gear set. As is known, a minus planetary gear set includes planet gears, which are rotatably mounted on a planet carrier or carrier, and which intermesh with the sun gear and the ring gear of this planetary gear set, such that with the planet carrier held and the sun gear rotating, the ring gear rotates in the direction of rotation counter to that of the sun gear.

Where permitted by a connection of the individual elements, a minus planetary gear set is convertible into a plus planetary gear set, wherein, as compared to the minus planetary gear set, the ring gear connection and the planet carrier connection are then to be interchanged, and a stationary transmission ratio is to be increased by one. Conversely, a plus planetary gear set is replaceable by a minus planetary gear set, provided the connection of the elements of the transmission enables this. In this case, as compared to the plus planetary gear set, the ring gear connection and the planet carrier connection are then to be interchanged, and a stationary transmission ratio is to be reduced by one.

It is also preferred that the first planetary gear set is a minus planetary gear set and the second planetary gear set is a plus planetary gear set, wherein the first element of the first planetary gear set is a sun gear, the second element of the first planetary gear set is a planet carrier, and the third element of the first planetary gear set is a ring gear, wherein the first element of the second planetary gear set is a sun gear, the second element of the second planetary gear set is a ring gear, and the third element of the second planetary gear set is a planet carrier.

As is known, a plus planetary gear set includes inner and outer planet gears, which are rotatably mounted on the planet carrier of the plus planetary gear set and are in tooth engagement with one another, wherein the sun gear of this planetary gear set intermeshes with the inner planet gears, and the ring gear of this planetary gear set intermeshes with the outer planet gears, such that with the planet carrier held and the sun gear rotating, the ring gear rotates in the same direction of rotation as the sun gear.

It is further preferred that a variable first mode, in particular a first forward mode, is implemented when the third shift element is engaged, and/or, wherein a power-split second mode, in particular a second forward mode, is implemented when the second shift element is engaged, and/or, wherein a variable third mode, in particular a first reverse mode, is implemented when the first shift element engaged.

It has been shown that a low variator load is achievable in the second mode.

In one refinement of the invention, an electric machine is provided, the rotor of which is coupled in a rotationally fixed manner to one of the rotatable components of the transmission, i.e., to the input shaft, the output shaft, one of the shafts, or to one of the three elements of the planetary gear sets. It is preferred that a stator of the electric machine is rotationally fixed to the rotationally fixed component of the transmission. In addition, the electric machine is operable, in this case, in particular, as an electric motor and/or as a generator in order to implement different functions. In particular, purely electric driving, boosting via the electric machine, deceleration and recuperation, and/or synchronization in the transmission is implementable via the electric machine in this case. The rotor of the electric machine can lie coaxial to the respective component or axially offset with respect thereto in this case, wherein, in the latter case, a coupling via one or multiple intermediate transmission ratio steps, for example, as spur gear stages, or even a flexible traction drive mechanism, such as a chain or belt drive, are then implementable.

Preferably, however, the rotor of the electric machine is coupled in a rotationally fixed manner to the input shaft, wherein, as a result, purely electric travel of the motor vehicle is implemented in a suitable way. It is further preferred when one or several of the shift elements is/are utilized as internal starting components for electric driving. As an alternative, however, a separate launch clutch is usable, which is positioned between the electric machine and the variator unit.

According to yet another design option of the invention, which is implemented, in particular, in combination with the aforementioned arrangement of an electric machine, a separating clutch is also provided, via which the input shaft is connectable in a rotationally fixed manner to a connecting shaft. The connecting shaft is utilized within a motor vehicle drive train as the connection to the drive machine. Providing the separating clutch has the advantage, in this case, that a connection to the driving machine is interruptible during the purely electric driving, whereby the drive machine is not entrained. The separating clutch is preferably, in this case, a friction-locking shift element, such as a multi-disk clutch, although the separating clutch can just as well be a form-fit shift element, such as a dog clutch or a lock-synchronizer mechanism.

The transmission according to the invention is, in particular, part of a motor vehicle drive train and is arranged between a drive machine of the motor vehicle, which is, in particular, an internal combustion engine, and further components of the drive train, which follow in the direction of power flow to driving wheels of the motor vehicle. In this case, the input shaft of the transmission is either permanently coupled to a crankshaft of the internal combustion engine in a rotationally fixed manner or is connectable thereto via an intermediate separating clutch or a starting component, wherein a torsional vibration damper is also providable between the internal combustion engine and the transmission. On the output end, the transmission is then preferably coupled, within the motor vehicle drive train, to an axle transmission of a drive axle of the motor vehicle, wherein a connection to an interaxle differential is also optionally present in this case via which a distribution to multiple driven axles of the motor vehicle takes place. The axle transmission or the interaxle differential can be arranged with the transmission in one common housing in this case. A torsional vibration damper can also be integrated into this housing.

Within the meaning of the invention, the expressions that two components of the transmission are “connected” or “coupled” in a rotationally fixed manner or “are connected to each other” mean a permanent connection of these components, and therefore said components cannot rotate independently of each other. In that respect, no shift element is provided between these components, which can be elements of the planetary gear sets and/or even shafts and/or a rotationally fixed component of the transmission. Instead, the corresponding components are rigidly connected to each other.

However, if a shift element is provided between two components of the transmission, these components are not permanently coupled to each other in a rotationally fixed manner. Instead, a rotationally fixed coupling is carried out only by actuating the intermediate shift element. In this case, an actuation of the shift element means, within the meaning of the invention, that the respective shift element is transferred into an engaged condition and consequently synchronizes the turning motions of the components coupled directly thereto. In the case of an embodiment of the respective shift element as a form-fit shift element, the components directly connected to each other in a rotationally fixed manner via the shift element rotate at the same rotational speed, while, in the case of a friction-locking shift element, speed differences can exist between the components even after an actuation of the shift element. This intentional or unintentional condition is nevertheless referred to, within the scope of the invention, as a rotationally fixed connection of the respective components via the shift element.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in greater detail with reference to the following figures. In the figures, the following is shown:

FIG. 1 shows a schematic view of a transmission device according to the invention in a preferred first embodiment;

FIG. 2 shows a shift pattern of the transmission device according to FIG. 1;

FIG. 3 shows a schematic view of a transmission device according to the invention in a preferred second embodiment;

FIG. 4 shows a shift pattern of the transmission device according to FIG. 3;

FIG. 5 shows a schematic view of a transmission device according to the invention in a preferred third embodiment;

FIG. 6 shows a schematic view of a transmission device according to the invention in a preferred fourth embodiment;

FIG. 7 shows a schematic view of a transmission device according to the invention in a preferred fifth embodiment; and

FIG. 8 shows a schematic view of a transmission device according to the invention in a preferred sixth embodiment.

DETAILED DESCRIPTION

Reference will now be made to embodiments of the invention, one or more examples of which are shown in the drawings. Each embodiment is provided by way of explanation of the invention, and not as a limitation of the invention. For example, features illustrated or described as part of one embodiment can be combined with another embodiment to yield still another embodiment. It is intended that the present invention include these and other modifications and variations to the embodiments described herein.

FIG. 1 shows a schematic of a power-split continuously variable transmission device 100 in the form of a mechanical IVT transmission which, in the area of an input shaft 1, is operatively connected directly, i.e., without a coupling device, to a drive machine (not represented). The drive machine is an internal combustion engine in the form of a diesel engine or a gas engine.

A torque which is made available by the drive machine and is present in the area of the input shaft 1 is guidable along multiple power paths, wherein a variator 10 is provided for varying a ratio of the respective power path, whereby the overall gear ratio of the transmission device 100 is continuously variable to the desired extent via the variator 10.

The shares of the torque present on the transmission input side in the area of the input shaft 1, which are guided along the power paths, are guided in the direction of the output shaft 6.

The transmission 100 further includes a first shift element B1, a second shift element K1, a third shift element B2 and one first planetary gear set RS1 connected to the variator 10. The transmission 100 also includes a second planetary gear set RS2 which is connected to the first planetary gear set RS1. Each of the first and third shift elements B1, B2 is a brake, and the second shift element K1 is a clutch. The first and second planetary gear sets are preferably simple (minus) planetary gear sets.

The variator 10, the first, second, and third shift elements B1, K1, B2 and the first and second planetary gear sets RS1, RS2 are arranged between the input shaft 1 and the output shaft 6 of the transmission 100.

The first planetary gear set RS1 includes a first element E11, a second element E12, and a third element E13, and the second planetary gear set RS2 includes a first element E21, a second element E22, and a third element E23, wherein the first element E11, E21 of each of the first and second planetary gear sets RS1, RS2 is a sun gear SO1, SO2, the second element E12, E22 of each of the first and second planetary gear sets RS1, RS2 is a planet carrier or carrier PT1, PT2, and the third element E13, E23 of each of the first and second planetary gear sets RS1, RS2 is a ring gear HO1, HO2.

In a known way, the sun gear SO1, SO2 intermeshes with one or several planet gears PR1, PR2, which are rotatably mounted on the planet carrier PT1, PT2 and intermesh with the ring gear HO1, HO2. The ring gear HO1 of the first planetary gear set RS1 is connectable or coupleable to the transmission housing GG via the first shift element B1 (i.e. first brake B1) and the ring gear HO2 is connectable or coupleable to the transmission housing GG via the third shift element B2 (i.e. second brake B2).

The variator 10 is a NuVinci variator. As is known, a NuVinci variator has a primary side 11 and a secondary side 12. In addition, it is fixed to the transmission housing. The primary side 11 is rotationally fixed to the input shaft 1 of the transmission 100. The secondary side 12 of the variator 10 is rotationally fixed via a third shaft 3 to the sun gear SO2 of the second planetary gear set RS2.

The sun gear SO1 of the first planetary gear set RS1 is rotationally fixed to the ring gear HO2 of the second planetary gear set RS2 via a fifth shaft 5. In addition, the fifth shaft 5 is fixable to a rotationally fixed component, such as a transmission housing GG. If the second brake B2 is activated, the sun gear SO1 of the first planetary gear set RS1 and the ring gear HO2 of the second planetary gear set RS2 are prevented from turning.

The ring gear HO1 of the first planetary gear set RS1 is rotationally fixed to the carrier PT2 of the second planetary gear set RS2 via a fourth shaft 4. The fourth shaft 4 is also fixable to the transmission housing GG via the first brake Bl. Moreover, the fourth shaft 4 is rotationally fixable to the input shaft via the third shift element K1 (i.e. clutch K1). If the first brake B1 is activated, the ring gear HO1 of the first planetary gear set RS1 and the carrier PT2 of the second planetary gear set RS2 are prevented from turning.

The planet carrier PT1 of the first planetary gear set RS1 is rotationally fixed to the output shaft 2, so that the carrier PT1 forms the driven end 2 of the transmission 100.

In this case, a first range of ratios or first mode V1 and a second range of ratios or second mode V2 for forward travel and a third range of ratios or third mode R1 for travel in reverse are implementable in the transmission device 100 by selective control of the first, second, and third shift elements B1, K1, B2. The changeover between the first, second, and third modes V1, V2, R1 takes place by the alternate opening and closing of two of the first, second, and third shift elements B1, K1, B2 at a speed-synchronized point.

The first and second planetary gear sets RS1, RS2 are arranged axially adjacent to each other in order to enable the transmission device 100 to be in an installation-space-favorable manner in the radial direction. The first planetary gear set RS1 is arranged axially between the variator 10 and the second planetary gear set RS2.

Through the selection of suitable ratios, the sun gear SO1 and the ring gear HO1 of the first planetary gear set are operable at the same circumferential speed, although in opposite directions, so that the output carrier PT1 is at a standstill, i.e., the rotational speed of the output carrier PT1 is zero. If the rotational speed of the sun gear SO1 of the first planetary gear set RS1 is now changed by an adjustment of the variator ratio, the carrier PT1 begins to turn. The vehicle starts. In this way, a launch clutch is omitted in an advantageous way.

FIG. 2 shows a shift pattern of the transmission device 100, in table form. As shown in the shift pattern, in order to implement the first range of ratios V1 for forward travel, the first shift element B1 is to be engaged, while the second and third shift elements K1, B2 are in the disengaged operating condition. If there is an appropriate demand for implementing the second range of ratios V2 for forward travel, the first shift element B1 is to be disengaged if the first range of ratios V1 for forward travel is presently engaged, the second shift element K1 is to be engaged, and the third shift element B2 is left in the disengaged operating condition. However, if there is an appropriate demand for implementing the third range of ratios R1 for travel in reverse, the third shift element B2 is to be engaged, while the first and second shift elements B1, K1 are to be transferred into or kept in the disengaged operating condition, respectively.

When the first range of ratios V1 for forward travel is engaged, the total torque introduced into the transmission device 100 via the input shaft 1 is guided via the variator 10 in the direction of the output shaft 2 without power splitting, whereby the first range of ratios V1 is a so-called direct mode, the spread of gear ratios of which corresponds to the spread of gear ratios of the variator 10.

When the second range of ratios V2 for forward travel is engaged, a lesser first share of the torque introduced into the transmission device 100 via the input shaft 1 is guided via the variator 10 in the direction of the output shaft 2 and a greater second share of the torque is guided into the second planetary gear set RS2 via the clutch K1 and the fourth shaft 4. Therefore, the power flow in the second range of ratios V2 takes place in a power-split manner.

When the third range of ratios R1 for travel in reverse is engaged, the total torque introduced into the transmission device 100 via the input shaft 1 is guided via the variator 10 in the direction of the output shaft 2 without power splitting, whereby the third range of ratios R1 is also a so-called direct mode, the spread of gear ratios of which corresponds to the spread of gear ratios of the variator 10.

A ratio of the transmission device 100 is continuously variable within each of the first, second, and third modes V1, V2, R1 via the variator 10.

FIG. 3 shows the transmission in a nested gear set arrangement, i.e., the second planetary gear set RS2 is arranged radially outside the first planetary gear set RS1. This is possible due to the fixed sun gear-ring gear coupling, i.e., the fixed connection between the sun gear SO2 of the second planetary gear set RS2 and the ring gear HO1 of the first planetary gear set RS1. As a result, an even more axially compact version of the transmission 100 is possible.

FIG. 4 shows a shift pattern, in table form, of the transmission device 100 according to the embodiment in FIG. 3. The shift pattern is identical to the shift pattern according to FIG. 2 such that reference can be made to the comments made with respect to FIG. 2.

FIG. 5 shows the transmission device 100 in one further embodiment. The transmission 100 includes a plus planetary gear set, wherein the second planetary gear set RS2 is the plus planetary gear set in FIG. 5.

The following nomenclature applies for a plus planetary gear set: the first element is the sun gear, the second element is the ring gear, and the third element is the planet carrier or carrier. Therefore, the carrier connection and the ring gear connection are simultaneously interchanged and the value of the stationary transmission ratio is increased by the value one.

In FIG. 5, the second planetary gear set RS2 includes the same sun gear SO2, inner and outer planet gears PR21, PR22, which are rotatably mounted on the planet carrier PT2 (third element E23), and a ring gear HO2 (second element E22). Due to the interchange, the planet carrier PT2 of the second planetary gear set RS2 is rotationally fixed to the sun gear SO1 of the first planetary gear set RS1 and the ring gear HO1 of the first planetary gear set RS1 is rotationally fixed to the planet carrier PT2 of the second planetary gear set RS2. The planet carrier PT2 of the second planetary gear set RS2 is connectable or coupleable to the first brake B1 and to the clutch K1.

Moreover, the driven end 2 is formed by the second element E12 of the first planetary gear set.

The shift pattern explained with reference to FIG. 2 applies for the embodiments according to FIG. 5.

FIGS. 6 to 8 show the transmission 100 in a hybrid application in three embodiments. The input shaft 1, in particular, is suitable for the connection of an electric machine EM.

The transmission according to FIG. 6 includes an electric machine EM, a stator S of which is rotationally fixed to the rotationally fixed component GG, while a rotor R of the electric machine EM is rotationally fixed to the input shaft 1. Moreover, the input shaft 1 is rotationally fixable, at the mounting interface 1-A, via an intermediate separating clutch KO which is a lamellar shift element in this case, to a connecting shaft AN which, in turn, is connected to a crankshaft of the drive machine (not represented). Due to the rotationally fixed connection of the rotor R to the input shaft 1, the electric machine EM is located coaxially to the input shaft 1.

Purely electric driving is implementable via the electric machine EM, wherein, in this case, the separating clutch K0 is disengaged in order to decouple the input shaft 1 from the connecting shaft AN and to not entrain the internal combustion engine. All continuously variable modes are also usable electrically. A start into the internal combustion engine-driven modes is always possible. For the rest, the embodiment according to FIG. 6 corresponds to the variant according to FIG. 1, and therefore reference is made to the description thereof.

Moreover, FIG. 7 shows a schematic view of a transmission 100 according to a further design option of the invention, which largely corresponds to the preceding variant represented in FIG. 7. The difference is that the electric machine EM is not arranged coaxially, but rather axially offset with respect to the input shaft 1. Consequently, a rotor (not represented in detail in this case) of the electric machine EM and the input shaft 1 are also not connected to each other in a rotationally fixed manner, but rather are coupled to each other via an intermediate spur gear stage SRS. In this case, a spur gear SR1 of the spur gear stage SRS is located on the input shaft 1 in a rotationally fixed manner and intermeshes with a spur gear SR2 which is arranged, in a rotationally fixed manner, on an input shaft EW of the electric machine EM. This input shaft EW then establishes the connection to the rotor within the electric machine EM. For the rest, the embodiment according to FIG. 7 corresponds to the variant according to FIG. 6, and therefore reference is made to the description thereof.

In addition, FIG. 8 shows a schematic of a transmission 100 according to a further embodiment of the invention, which also essentially corresponds again to the variant according to FIG. 4. As is already the case with the embodiment according to FIG. 7, the electric machine EM is not arranged coaxially, however, but rather axially offset with respect to the input shaft 1. A rotationally fixed coupling between the input shaft 1 and a rotor (not represented) of the electric machine EM is achieved in this case via a flexible traction drive mechanism ZT which is preferably a chain drive. This flexible traction drive mechanism ZT couples the input shaft 1 to an input shaft EW of the electric machine EM in this case. Otherwise, the variant according to FIG. 8 corresponds to the embodiment according to FIG. 6, and therefore reference is made to the description thereof.

With the aid of the embodiments according to the invention, a transmission having a compact design and good efficiency can be implemented.

Modifications and variations can be made to the embodiments illustrated or described herein without departing from the scope and spirit of the invention as set forth in the appended claims.

REFERENCE CHARACTERS

1 input shaft

2 output shaft

3 third shaft

4 fourth shaft

5 fifth shaft

10 variator unit, variator, NuVinci variator

100 power-split continuously variable transmission device, continuously variable planetary transmission

An connecting shaft

B1 first shift element, brake

B2 third shift element, brake

E11 first element

E12 second element

E13 third element

E21 first element

E22 second element

E23 third element

EM electric machine

HO1 first ring gear

HO2 second ring gear

K0 separating clutch

K1 second shift element, clutch

RS1 first planetary gear set

RS2 second planetary gear set

SO1 first sun gear

SO2 second sun gear

PR1 planet gear

PR2 planet gear

PR21 inner planet gear

PR22 outer planet gear

PT1 first planet gear carrier, carrier

PT2 second planet gear carrier, carrier

R1 third mode, reverse

R rotor

S stator

SRS spur gear stage

SR1 spur gear

SR2 spur gear

ZT flexible traction drive mechanism

V1 first mode, forward

V2 second mode, forward 

1-12. (canceled)
 13. A power-split continuously variable transmission device (100), comprising: an input shaft (1); an output shaft (2); a first planetary gear set (RS1) arranged between the input shaft (1) and the output shaft (2); a second planetary gear set (RS2) connected to the first planetary gear set (RS1) and arranged between the input shaft (1) and the output shaft (2); and a variator unit (10) for transmitting power in a continuously variable manner from the input shaft (1) to the first planetary gear set (RS1), the variator unit (10) having a first shift element (B1), a second shift element (K1) and a third shift element (B2), selective actuation of the first, second and third shift elements (B1, K1, B2) implements different power paths via the variator unit (10) and the first and second planetary gear sets (RS1, RS2) while making a first mode (V1), a second mode (V2), and a third mode (R1) available, wherein the variator unit (10) is fixed to a rotationally fixed component (GG), a primary side (11) of the variator unit (10) is rotationally fixed to the input shaft (1), and a secondary side (12) of the variator unit is rotationally fixed to a first element (E21) of the second planetary gear set (RS2) via a third shaft (3), wherein a third element (E13) of the first planetary gear set (RS1) is rotationally fixed to a second element (E22) of the second planetary gear set (RS2) via a fourth shaft (4), the second element (E22) of the second planetary gear set (RS2) fixable to the rotationally fixed component (GG) via the first shift element (B1) and connectable to the input shaft (1) via the second shift element (K1), wherein a third element (E23) of the second planetary gear set (RS2) is rotationally fixed to a first element (E11) of the first planetary gear set (RS1) via a fifth shaft (5), the first element (E11) of the first planetary gear set (RS1) fixable to the rotationally fixed component (GG) via the third shift element (B2), and wherein the second element (E12) of the first planetary gear set (RS1) is rotationally fixed to the output shaft (2).
 14. The transmission device (100) of claim 13, wherein the variator unit (10) is a NuVinci variator.
 15. The transmission device (100) of claim 13, wherein the first and second planetary gear sets (RS1, RS2) are arranged axially adjacent to each other.
 16. The transmission device (100) of claim 13, wherein the first planetary gear set (RS1) is arranged radially outside the second planetary gear set (RS2).
 17. The transmission device (100) of claim 13, wherein: each of the first and second planetary gear sets (RS1, RS2) is a minus planetary gear set; the first element (E11) of the first planetary gear set (RS1) is a sun gear (SO1); the second element (E12) of the first planetary gear set (RS1) is a planet carrier (PT1); the third element (E13) of the first planetary gear set (RS1) is a ring gear (HO1); the first element (E21) of the second planetary gear set (RS2) is a sun gear (SO2); the second element (E22) of the second planetary gear set (RS2) is a planet carrier (PT2); and the third element (E23) of the second planetary gear set (RS2) is a ring gear (HO2).
 18. The transmission device (100) of claim 13, wherein: the first planetary gear set (RS1) is a minus planetary gear set and the second planetary gear set (RS2) is a plus planetary gear set; the first element (E11) of the first planetary gear set (RS1) is a sun gear (SO1); the second element (E12) of the first planetary gear set (RS1) is a planet carrier (PT1); the third element (E13) of the first planetary gear set (RS1) is a ring gear (HO1); the first element (E21) of the second planetary gear set (RS2) is a sun gear (SO2); the second element (E22) of the second planetary gear set (RS2) is a ring gear (HO2); and the third element (E23) of the second planetary gear set (RS2) is a planet carrier (PT2).
 19. The transmission device (100) of claim 13, wherein: the first mode (V1) is variable and implemented when the third shift element (B2) is engaged, and/or the second mode (V2) is power-split and implemented when the second shift element (K1) is engaged, and/or the third mode (R1) is variable and implemented when the first shift element (B1) is engaged.
 20. The transmission device (100) of claim 13, further comprising an electric machine (EM), a rotor (R) of the electric machine (EM) is connected to the input shaft (1), the third shaft (3), the fourth shaft (4), the fifth shaft (5), one of the first, second, or third elements (E11, E12, E13, E21, E22, E23) of the first and second planetary gear sets (RS1, RS2) or to the output shaft (2).
 21. The transmission device (100) of claim 20, further comprising a separating clutch, the input shaft (1) rotationally fixable to a connecting shaft via the separating clutch.
 22. The transmission device (100) of claim 20, wherein the electric machine (EM) is arranged coaxially to the input shaft (1).
 23. The transmission device (100) of claim 20, wherein the electric machine (EM) is arranged axially parallel to the input shaft (1).
 24. A motor vehicle drive train comprising the transmission device (100) of claim
 13. 